DE567726C - Device for synchronizing electrical clock systems - Google Patents

Description

Device for synchronizing electrical clock systems Invention concerns synchronizing clock systems. in which the slave clocks through Pulses from the master clock are advanced and during the synchronization period by - a series of rapid impulses are presented.

In such clock systems it is known to initiate the slave clocks electrically to provide releasable locking devices. which serve to introduce the slave clocks to prevent beyond the right time. With the known clock systems of this type, the locking devices require special lines. because with the switching and synchronizing pulses are triggered with electrically identical pulses.

According to the invention, the slave clocks are required in relation to the per se known blocking organs have no special management, but care is taken to ensure that that the locking devices only respond to pulses generated by the switching and synchronization pulses are different, for example by their voltage, their duration or the like.

The locking devices for the slave clocks can either according to the invention Used directly as switching magnets for the slave clocks or as additional ones Control organs are assigned to the switching solenoids. In the former case the switching magnets of the. Slave clocks are provided with two windings, the are dimensioned and switched in such a way that with the normal progression of the clocks a Winding is reversed, while in the locked position of the clocks both windings are switched on in such a way that the magnet only respond to the release pulses and can thereby cancel the lock of the slave clocks at the given moment. the Switching magnets of the slave clocks can also act as a blocking element additional armature can be provided, which only responds to the release pulses. In In both of these cases, the effectiveness of the locking devices is dependent on the voltage addicted. In the case of the training of the blocking organs as additional control organs they can act as electrical thermostats in addition to the usual switching magnets, the effectiveness of which depends on the duration of the release pulses.

In the drawings, the subject matter of the invention is in some exemplary embodiments shown.

Figs. T and 2 show the embodiment with a solenoid for the slave clock, which is provided with two windings, Fig. t showing the circuit diagram the Clock system, the Fig. 2 the essential for the invention switching elements of a Represent slave clock.

Fig. 3 shows a modification with the same design of the master clock the slave clocks. whose switching magnet is provided with a simple winding.

Figs. 4 and 5 in the circuit arrangement and in individual representation show that which is assigned to the switching magnet of the slave clocks and is designed as a thermostat Relay that causes the slave clocks to be blocked.

In the circuit diagram of Fig. I, the master clock is schematically shown on the left shown, which by means of the usual gear mechanism that carries the minute hand Axis io drives, which makes one full revolution every hour. i i is the one with the not shown Steigrad -cooperating armature of the clock. At 12 and 15 are cam disks that are driven by the axis io and for Control of contacts 14 and 16 are used. Furthermore, a cam disk 18 is provided, which executes one revolution per minute and the minute impulse contact 17 closes and opens. The in Schnell is used to transmit the acceleration pulses Result working contact i g, which is under control of the armature i i.

Before describing the slave clocks, the various Operating conditions of the master clock are explained.

Switch 32 is located on the master clock for normal clock operation in the position shown. When sending out the ones intended for the slave clocks normal switching impulses via line 37, the following processes take place: Current flows from earth G on the master clock through battery B via the switch 32, the line 33, the minute pulse contact 17, the relay winding 34 back to Earth G. By energizing the relay 34 is its contact 35 once in each Minute closed, whereby low-voltage current pulses are sent into the line 37 which take the following course: earth G, right part of battery B, line 42, contact 43 of relay 4o, line 45, contact 35 of relay 34, line 37, Switching magnets 21 of the slave clocks and back to earth G.

It should be noted that for the supply of the low-voltage current, which is only given off by part of the battery B, only a single path is available is and that in this way the feeding of the minute pulses takes place. Of course other types of current paths can also be provided through which one of two Currents of different voltages are conducted.

At a predetermined point in time, for example once every hour, the contact 16 is closed for about 30 seconds or, if desired, longer, namely the closing of the contact 16 precedes the fifty-ninth minute. In this case, a current flows through the contact ig, which closes and opens in rapid succession, whereby the relay 34 is energized and de-energized in quick succession, so that a series of current pulses is sent out over the line 37. These current impulses also have a low voltage, and they cause the subsequent slave clocks to switch more quickly. Exactly at the fifty-ninth minute or, if so desired, at shorter intervals, the contact 14 is closed, with the result that the relay 4o is energized and its contacts 43 and 43a are opened or closed. With the excitation of the relay 4o, the full voltage of the battery B is now applied to the line 37, so that at least one, but preferably several current pulses of higher voltage are sent into the line 37. These high-voltage current impulses switch those slave clocks which, as will be explained below, have to be set.

The switch 32 has three switch positions. By his attitude In the middle position, all slave clocks can be switched off completely. If it is desired to manually advance the slave clocks at any time, so it only needs to set the switch 32 in its upper switch position, whereby the armature contact ig is connected to the battery B.

In the circuit diagram of Fig. I, three slave clocks are provided, which are connected in parallel to line 37 and to earth G. The slave clocks are therefore connected to the master clock via just one line. Instead of the earth connection A wire return can of course also be provided. In this case leads One supply and one return line each to the slave clocks.

The slave clocks are designed as follows: each slave clock has one Switching solenoid 2 1, the several, z. B. has two windings 21 and 21d. Zia is the usual pawl that is engaged with the ratchet 2a, whose Axis 2o makes one revolution every hour. On the axis 2o also sits a den Contact 51 controlling cam disk 5o. Through this contact, the Development -21d of the switching magnet 21 short-circuited «-earth, while in the open state of contact 5 r the windings 2id LIIld -21e are connected in series. The winding 2, d has a smaller number of turns than winding 21 C, and both windings are wound in the opposite direction with respect to their winding direction.

If a slave clock. whose winding 21d is short-circuited, receives low-voltage current pulses, the winding 21c is sufficiently strong: excited to advance the clock by one switching step by means of the pawl 21a. With such slave clocks, however, the winding 21d of which is not short-circuited at the moment, there is no excitation of the magnet 21- sufficient for switching on, since the weak pulses are not sufficient for this purpose. In this case the magnet can only be energized by higher voltage current impulses. The reasons for this will be explained in more detail below: Assume a number of turns of 2ooo for winding 21d with an ohmic resistance of 50o and for winding 21v 4ooo turns with a resistance of r,000 ohms and .10 ampere turns. in order to magnetize the core so strongly that the armature carrying the pawl 2 can be attracted, then for those slave clocks whose \\ 'ik7kltirig 21d is short-circuited, at a current strength of io: iooc ".mpere # 4ooo 4o ampere turns , which are sufficient to excite the solenoid 21 sufficiently strongly. But if the windings 2ic and 21 << are connected in series, so the winding 21d is not short-circuited, so that a total resistance of 150 ohms comes into consideration, then the current strength is the same for the same voltage of 10 volts - that is, 0.06 amps . The number of ampere turns of winding 21 t 'would therefore be 4000 # o, oo6 - 24, and that of winding 2i d --ooo # o, oo6 - 12. As a result of the counteraction of windings 2ic and 2id, the actual number of ampere-turns is 24-i2 - r2; which is not sufficient to switch the latch eia.

If one assumes a voltage of 40 volts instead of the 10 volt voltage, the strength of the current flowing through the series-connected windings 2 ic and 2, d would be 40: 15, i.e. 1i. be about 0.024 amps. The number of ampere-turns of winding 2ic is then .I000 # 0.024, i.e. about 96, and that of winding 2 id is 2000 # 0.024 ==. 48. The effective number of ampere-turns is therefore 96 - 48 - 48, which is sufficient. to switch the pawl 21a. Accordingly, in the exemplary embodiment described, provision is made to use low-voltage current for the normal switching pulses to be sent out by the master clock. Periodically, a number of rapid pulses are sent out on line 37, which are also of low voltage. The following slave clocks are advanced by these pulses until contact 51 is opened. The correct slave clocks would also be advanced by the pulses if contact 51 did not prevent these clocks from being advanced. In the previous clocks, the contact 51 is already open. because it opens as soon as the minute hand of the clock in question reaches the fifty-ninth minute. At this point in time, regardless of the arrival of further normal or rapid pulses, these remain ineffective with regard to the advancement of the slave clock. However, when the master clock reaches the fifty-ninth minute, it sends at least one. possibly also several current pulses of higher voltage. As a result, the slave clocks that have already been stopped are restarted and the contact 51 is opened, whereupon they are ready to receive the normal switching pulses again. It is clear that the timing of the synchronization can be determined by appropriate dimensioning and design of the cam disks 12 and 15 of the master clock and the cam disk 5o of the slave clocks.

According to the embodiment of Fig. 3, in the same parts with the same reference numerals are provided, the ratchet 22 of the NT slave clocks with a Stop 23 is provided which cooperates with a spring-loaded pawl 25 which is hinged to an additional armature 24 des`Schaltmagneten 21. The anchor 24 is under the action of a tension spring 26 and wildly by this from the core of the Shift solenoid withdrawn. The tensile force of the spring 26 is greater than that of the spring 26a, which acts on the armature of the magnet 21 carrying the pawl Zia, and so dimensioned that the armature 24 is under the action of the normal switching pulses cannot be attracted.

The contact 16 is hourly before the fifty-ninth minute for the duration of e.g. B. closed for 30 seconds. whereby a number of current pulses are sent out via the contact i9 into the line 37 leading to the slave clocks. The slave clocks that follow, for example, make switching steps in rapid succession, which continue until the stop 23 of the indexing wheel 22 meets the pawl 25 and accordingly the slave clocks cannot be switched beyond the fifty-ninth minute.

The slave clocks are triggered again, as already described above, with the help of the current pulses of higher voltage, which result from the excitation of the relay 40 get into the line 37 and a sufficiently strong excitation of the switching magnets 2i to overcome the tension of the spring 26, causing the stop 23 of the ratchet wheel 22 is released by the pawl 25. In the subsequent supernatural excitement of the switching magnet 21, which occurs as soon as the relay 34 is de-energized again, the Klinke2ia switches the ratchet 22 uni one step forward. With the excitement of the magnet 2i, the pawl 25 with your armature z4 goes back into the blocking position, and the normal progression of the clocks continues until the blocking of the ratchet wheel 22 takes place again by the pawl 25.

In Fig. 4, the two cam disks 12 and 15 sit on the minute axis the master clock, of which the cam disk 15, the contact 16 and the cam disk 12 controls contact 14. The contact 16 is preferably 5o seconds before closed on the full hour, while contact 14 et- # va = o seconds before the full hour Closed on the hour and open on the hour.

The slave clocks in turn have the usual ratchet wheel 22, which by the switching pawl Zia controlled by the switching magnet 21 is moved. Each ratchet 22 carries a stop 52 with which the relay 53, designed as a thermostat, acts as a limit stop cooperates. The relay 53 and the cam 52 are arranged to each other that it is blocked as soon as the minute hand of the slave clock reaches the full hour. The winding of the relay 53 is connected in series with the winding of the switching magnet 21. The relay winding and its action on the flexible core 54 is dimensioned so that current pulses of short duration cannot cause a heating effect, but only a long, uninterrupted flow of current, which is caused by the closure of contact 14 comes about. Here, the core 54 of the relay 53 is heated so that it can assumes the state indicated by dotted lines in Fig. 5, in which it assumes the stop 52 of the ratchet wheel 22 releases.

The operation of the relay 53 is as follows: About 20 seconds before contact 14 is closed on the hour and closed until the hour held. This causes the relay 34 to be energized and on for the duration of: o seconds correspondingly long current pulse through the contact 35 and the line 37 according to the Slave clocks directed. The switching magnet 21 and with it the relay 53 are energized. This energization of the relay 53 causes the core 54 to bend out of its basic position out and thus the release of the stop 52 of the ratchet wheel 22. As soon as the power supply is interrupted again, the slave clocks can be activated by the normal minute switching impulses be operated again.

Claims (5)

PATENT INSPECTION: 1. Synchronizing clock system, in which the Slave clocks advanced by pulses from the master clock during the synchronization period be presented by a series of rapid impulses and with an electric Triggerable locking device to prevent people from imagining the correct one Time are also provided, characterized in that the locking members only respond to pulses generated by the switching and synchronization pulses, for example are electrically different due to their voltage, their duration or the like. 2. Establishment according to claim i, characterized in that the indexing magnets of the slave clocks wear two windings, which are dimensioned and connected so that with the normal Continuation of the clocks one winding is ineffective while in the locked position of the clocks both windings are turned on in such a way that the magnet only hits the Release impulse responds. 3. Device according to claim i, characterized in that that the switching magnet (z1) of the slave clocks an additional acting as a blocking element Armature (24) has, which only responds to the release pulses. 4. Set up after Claim i, characterized in that an electric thermostat is used as the blocking element (53, 54) is used. 5. Device according to claim 4, characterized in that the electric thermostat with its heating winding (53) with the excitation winding of the Switching magnet (21.) is connected in series.